Looking up has never felt more important.<\/strong> Mars today is a bone-dry desert world. But a few billion years ago, you could have played in rain puddles or perhaps a snowbank. That\u2019s the conclusion of a new study from researchers at the University of Colorado Boulder. The geologists said on April 21, 2025, that heavy precipitation \u2013 either rain or snow or both \u2013 likely formed and fed many of the river channels and valleys that we can still see clearly etched into the Martian surface. The new evidence supports the scenario that early Mars was at least relatively warm and wet.<\/p>\n The researchers published their peer-reviewed findings in the Journal of Geophysical Research: Planets<\/em> on April 21, 2025.<\/p>\n University of Colorado Boulder: Did It Rain or Snow on Ancient Mars? New Study Suggests It Did www.colorado.edu\/today\/2025\/0\u2026<\/p>\n \u2014 AAS Press Office (@press.aas.org) 2025-04-22T15:05:50.614Z<\/p>\n<\/blockquote>\n The findings add to the debate of whether Mars was always cold and dry or if it was warmer and wetter billions of years ago. Some scientists think it was warmer, while others say it was cold. Even after decades of research and exploration of Mars by rovers and landers, they have not come to a consensus.<\/p>\n We know that Mars has long had abundant ice, both at its poles and underground, but was that water ever liquid? Ancient riverbeds, lake deposits and even possible ocean sediments \u2013 and vacation-style beaches \u2013 suggest it was. But how?<\/p>\n Jezero crater, which NASA\u2019s Perseverance rover is exploring, was once a lake. Like Gale crater, a river once flowed into this lake. The rover has studied the ancient river delta inside the crater, which we can still easily see from orbit. Perseverance found large boulders that the river transported. And that required a lot<\/em> of water. Co-author Brian Hynek at the Laboratory for Atmospheric and Space Physics (LASP) at the University of Colorado Boulder said:<\/p>\n You\u2019d need meters deep of flowing water to deposit those kinds of boulders.<\/p>\n<\/blockquote>\n It\u2019s apparent that Mars was once awash in water. And not just as frozen ice. Lead author Amanda Steckel was at the University of Colorado Boulder for the study and is now at the California Institute of Technology (Caltech). She said:<\/p>\n It\u2019s very hard to make any kind of conclusive statement, but we see these valleys beginning at a large range of elevations. It\u2019s hard to explain that with just ice. You could pull up Google Earth images of places like Utah, zoom out, and you\u2019d see the similarities to Mars.<\/p>\n<\/blockquote>\n Watch: Earth or Mars? Test yourself with this quick quiz<\/p>\n For their own study, the researchers used digital computer simulations to see how water would have shaped the Martian surface. Did rain or snow help form the channels and valleys, or was it just melting ice? The study suggests it was indeed rain or snow. Co-author Gregory Tucker at the Department of Geological Sciences at the University of Colorado Boulder originally developed this simulation model for Earth studies.<\/p>\n The model simulated terrain close to the Martian equator, where many of the old river channels can be found. In the simulation, water was added in two different ways, both as rain or snow and as ice. In addition, the researchers even simulated melting ice caps. The model simulated the flows of water for periods of tens to hundreds of thousands of years.<\/p>\n The simulations provided markedly different results depending whether the water was precipitation or melting ice. For example, with melting ice caps, the river valleys created were mostly at high elevations. They were also limited to the terrain around the edge of the melting polar ice cap. But it was different for the valleys created by precipitation, whether rain or snow. They were more widespread and at various elevations. Some were below the average surface elevation, while others formed at elevations up to 11,000 feet (3,300 meters).<\/p>\n Steckel said:<\/p>\n Water from these ice caps starts to form valleys only around a narrow band of elevations. Whereas if you have distributed precipitation, you can have valley heads forming everywhere.<\/p>\n<\/blockquote>\n So which scenario is closer to what we actually see on Mars? The precipitation one. The ancient riverbeds we see today are largely around the equator, far from where any meltwater from the ice caps would have flowed, and vary in elevation.<\/p>\n The results are yet more evidence for a much wetter Mars in the past. Scientists still don\u2019t know exactly how<\/em> the planet was able to maintain the warmth needed for as long as it did. But the Curiosity rover might have just helped that mystery, too. Another recent study focused on siderite carbonates the rover has found in Gale crater. They are evidence that Mars used to have a carbon cycle similar to that on Earth, and that the carbon dioxide atmosphere used to be much thicker and warmer than it is today. Liquid water could have been abundant in those conditions.<\/p>\n But those conditions didn\u2019t last, and Mars lost most of its atmosphere and water. As Hynek noted:<\/p>\n Once the erosion from flowing water stopped, Mars almost got frozen in time and probably still looks a lot like Earth did 3.5 billion years ago.<\/p>\n<\/blockquote>\n Incidentally, it does<\/em> still snow on Mars today. The Mars Phoenix lander recorded snow falling from clouds, NASA reported in 2008. In Mars\u2019 really thin atmosphere, however, the snowflakes evaporated before reaching the ground, at least in this location.<\/p>\n Bottom line: Did it rain on ancient Mars? A new study suggests that heavy precipitation \u2013 rain or snow \u2013 helped form rivers that fed into lakes billions of years ago.<\/p>\n Source: Landscape Evolution Models of Incision on Mars: Implications for the Ancient Climate<\/p>\n Via University of Colorado Boulder<\/p>\n Read more: How hard did it rain on Mars?<\/p>\n Read more: New discovery of carbonates on Mars could solve big mystery<\/p>\n <\/div>\n
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Did it rain on ancient Mars?<\/h3>\n
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Warm and wet or cold and dry?<\/h3>\n
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A digital simulation of Mars<\/h3>\n
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Ice or snow or rain on ancient Mars?<\/h3>\n
Strikingly different results<\/h3>\n
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How did Mars stay warm?<\/h3>\n
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